Status of MiniCal Analysis

1. Status of MiniCal Analysis E. Garutti (for DESY-HCAL group) • NEW run with Tile-HCAL prototype with MA-PM single tile read-out: •  improve systematic uncertainty •  improve comparison to SiPM • preliminary data/MC comparison Erika Garutti

2. New MA-PM Studies e+ • Main differences from October run: • Single tile readout for core of MiniCal •  direct comparison to SiPM • open beam collimator to get higher second particle rate •  1-12 GeV beam energy • fast MIP calibration with beam • less sensitivity to temperature & voltage fluctuations cell RO single tile RO Erika Garutti

3. MIP Calibration 3 GeV on single tile, w/o absorber in front • Pedestal determination: • 1 ADC channel shift = 1% uncertainty in s/E • MIP = MPV – pedestal • Gauss for peak position + Landau for tail: • variation of function boundaries = • 2% uncertainty in s/E Gauss Landau  2% fit systematic MIP Erika Garutti

4. MC simulation of MIP • implemented PM description in MC • single tile MC calibration needed: • - # ph.e /MIP • - width of 1st ph.e • good description of MIP shape after calibration •  More details in Marius talk Erika Garutti from M. Groll

5. Reproducibility of Calibration • calibrations performed • before and after energy • resolution scan • observed overall 2% shift  2% calibration reproducibility Erika Garutti

6. Slow Control Monitor • Daily monitor of MIP calibration versus: • temperature fluctuations • High Voltage stability • More details in Hendrik talk • related to temperature variation  2% calibration reproducibility Erika Garutti

7. Tile Calibration Scan 9 point scan of the tile centre according to:  2% tile homogeneity Erika Garutti

8. Two Particle Events ~8% of events have 2 particles hitting the MiniCal 2 particles from 2 GeV beam give the second peak @ 4 GeV  Max energy = 12GeV 2 GeV 4 GeV Erika Garutti

9. MC Simulation of Two-particle Events 13 layers MiniCal 26 layers MiniCal Res. = 27.6/438.3 = 6.30% Res. = 27.8/437.7 = 6.35% Erika Garutti from A. Raspereza

10. Linearity of PM Response 1.5% PM non-linearity Erika Garutti

11. Systematic Uncertainty s/E (%) Erika Garutti

12. Fit to Energy Resolution Determination of s/E from fit using with or w/o noise term • Little constrain from high energy data on constant term • (compare black/red curves) • SiPM response curve applied • SiPM sys. fixed to 5% • SiPM data are 7% above PM s/E (%) • SiPM • PM SIPM results from MEPHI group analysis Erika Garutti

13. Energy Resolution MC tuned to PM response • SiPM • PM • MC no sensitivity to c term Erika Garutti

14. Result Comparison Preliminary: Fixing a = 19.0 (MC value) SiPM: b = 5.1 ± 0.5 PM : b = 3.1 ± 0.5 MC : b = 4.6 ± 0.2  Still to be discussed within the group to understand source of constant term s/E (%) • SiPM • PM • MC Erika Garutti

15. N MIP comparison remaining difference in total number of MIP to be understood Erika Garutti

16. Outlook -many progresses made in: • control of data quality systematic uncertainty ( < 4% for PM) detectors comparison simulation • still to be understood: • difference in N MIPs on SiPM/PM • constant term of SiPM/PM • MC description of energy resolution • goal: • combined publication of SiPM/PM data • first draft in April Erika Garutti